System and method for direct device communication with diagnostics and provisioning

ABSTRACT

There are provided systems and methods for mobile device diagnostics and provisioning, whereby connections are effectuated to communicate directly with hardware of mobile devices to perform diagnostics and other functions such as device erasure without the need to first install an app on the mobile device. In this manner, information such as detailed product identification, vendor identification, and diagnostic information may be quickly obtained from the mobile device, and diagnostics and erasure undertaken to return a previously owned device into the stream of commerce in an efficient manner.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the full benefit of and priority to U.S.provisional patent application No. 62/899,616 filed Sep. 12, 2019titled, “SYSTEM AND METHOD FOR DIRECT DEVICE COMMUNICATION WITHDIAGNOSTICS AND PROVISIONING,” the disclosure of which is fullyincorporated by reference herein for all purposes.

FIELD OF THE INVENTION

This application relates to systems and methods for diagnosis ofoperational states of mobile devices and related provisioning for mobiledevices; more particularly, systems and methods of the presentapplication provide for assessment of functionality and performanceparameters through direct communication interfaces to mobile devicecomponents, and rapid and secure erasure of information stored on suchmobile devices.

BACKGROUND OF THE INVENTION

Today, the use of mobile devices is widespread, and increasing numbersof people utilize such devices in their daily lives. As used herein, theterm “mobile device,” generally refers to any electronic device capableof being moved from place to place. Examples of such mobile devicesinclude, but are not limited to cellular phones (also known moregenerally as “mobile phones”), smart watches, smart jewelry, portabledigital assistants (PDAs), digital cameras, intelligent devices for the“Internet of Things” (or “IOT”), drone devices, mobile subscribercommunication devices, tablet computers, media players, smart vehicles,laptop computers, and devices equipped with wireless intelligent agentsinstalled such as Alexa, Google Voice, Siri, Cortana, and others.Consumers purchase millions of mobile devices such as cellular phonesevery year, driven by the desire for enhanced features andfunctionality; replacement of worn, damaged, partially nonfunctional, orslower operating devices; or simply, just to obtain the latest productbased on consumer loyalty or to show off new models to friends andacquaintances. On the other hand, as more features and capabilities havebeen incorporated into newly-released mobile devices, the rapidlygrowing expense of such devices has created a secondary market forpre-owned but functional mobile devices. As such, an industry hasevolved to process and recycle previously-owned mobile devices to bringthem into operational condition for refurbishment and resale, or forparting out inoperable devices for valuable components or scrap.

Pre-owned mobile device processors (also known herein as “recyclers”),are faced with the challenge of taking in mobile devices such as usedmobile phones that are of unknown functionality and operational state,assessing the functional condition of such devices, securely erasing alldata from prior users from the mobile phones, and if necessary,effectuating any necessary repairs. With narrow profit margins arisingfrom the competitive market conditions and pricing for recycled mobiledevices, efficiency in the assessment, diagnostic, and erasure processis paramount. The recycler must quickly assess the type of device, itsoperational state, and conduct any necessary re-provisioning such asflashing and erasure of the mobile device in the most efficient mannerpossible to ensure that recycled devices are returned to the stream ofcommerce as quickly as possible.

In traditional mobile phone recycling processes, recyclers attempt toconnect mobile devices to power/data sources such as a USB or Lightningport, and if the device is not password protected, protected throughmobile device management (“MDM”), or through a cloud-based remoteactivation lock scheme such as Find My iPhone (“FMIP”), the recyclerattempts to install an application on the mobile device that may be usedfor diagnostics and/or device erasure. However, just assessing a devicetype or a device's state (such as whether it is locked or subject toMDM) can be problematic for devices that have been received in unknownworking condition or partially operable condition (and may also requireaccess to expensive third party databases to determine an activationlock status). Further, such installation of apps on the used mobiledevices is time consuming and may not be possible if the display of theused mobile devices is cracked/broken or sufficiently nonfunctional toprohibit interaction with the devices (such as to confirm permissionsthat allow the downloaded applications to function). Further, someincoming mobile devices may have batteries in a fully discharged state,and bringing such discharged devices to an initial condition that allowsinitial operation may require a time-consuming battery charge processbefore the device may be processed through theassessment/diagnostic/erasure procedures of the device recycler.

In addition to mobile device recyclers, retail organizations such asmobile carriers (also known as cellular phone service providers) arealso faced with the need to quickly assess, diagnose, and/or erasemobile devices brought in by customers in a retail setting or kiosk. Toprovide such a service, carriers were faced with purchasing andconfiguring expensive hardware to diagnose mobile phones potentially ineach retail location or kiosk. Further, even with existing test systemsor data transfer hardware, mobile devices needed to be unlocked and havea minimally functional display for a carrier to perform diagnosis andother functions on the mobile devices.

In sum, among other things, there is a need to provide systems andmethods to perform diagnostics and re-provisioning (such as re-flashingthe device or securely erasing) of mobile phones and other mobiledevices without first installing an app on such devices. Further, whatis needed are systems and methods to support diagnosis and provisioningof mobile devices in a retail setting with hardware commonly availablein such settings.

SUMMARY OF THE INVENTION

The following technical disclosure is exemplary and explanatory only andis not necessarily restrictive of the invention as claimed.

In one aspect, an embodiment of the present invention may, through aserial connection or a USB-type connection communicate directly with thehardware of mobile device to obtain relevant information from the devicewithout initial installation of an app on the mobile device. In variousembodiments of the present invention discussed more fully below,detailed product, vendor, and status information may be obtained fromthe mobile device quickly and even if a display of the mobile isnon-functional, or if a battery of the mobile device is in a dischargedstate. Further, diagnostics and certain provisioning actions may beperformed by a host system connected to a mobile device without the needto install an app on the mobile device. Additionally, in variousembodiments, a mobile carrier may conduct analytics and mobile deviceprovisioning in a retail setting without the need to purchase additionalhardware beyond a computer system configured to operate methods of thepresent invention along with interface cables as described herein. Inthe retail setting or in a kiosk, a mobile device may be attached to thetest system via a USB cable, and a web browser configured with a pluginmay operate on a computer or tablet of the retail vendor/kiosk toconduct diagnostic testing and/or provisioning of the connected mobiledevice in accordance with aspects of the invention described herein.

In additional embodiments of the present invention, thorough serialconnections established between and the mobile device and the hostsystem, sophisticated analytics, diagnostics, and provisioning functionssuch as erasure may be conducted without the need to have a user or testsystem first install an app on the mobile device. Further, variousembodiments may conduct diagnostics and provisioning of a mobile devicewithout rooting or jailbreaking the mobile devices from theirfactory-set condition.

In one implementation, an electronic system is interfaced to the mobileunit under test through a cable such as a serial cable, and preferably aUSB-compatible cable. In additional embodiments, the interconnectingcable may utilize an element that is intended to modify thevoltage/current profile passing between the cable to the mobile deviceunder test to activate particular functionality within circuits (such asin chip sets or controllers) that comprise the mobile device. In yetanother embodiment, the interconnecting cable is a USB On-The-Go (OTG)compatible cable, wherein the element is connected in-between theidentification (ID) pin and the ground (GND) pin. In an additionalembodiment, the element has a fixed resistance value. In yet anotherembodiment, the resistance value of the element may be variable, throughmanual techniques such as adjusting a potentiometer by hand, or throughautomated techniques, such as by changing the resistance value throughan interface to a digital potentiometer or an interface to an analoguesemiconductor component integrated within the cable. As set forth above,these embodiments utilizing an element with a fixed resistance value oran element with a variable resistance value are in addition to thepreferred embodiment of a standard USB cable (with pull-up resistorincluded, if so equipped).

There is provided a method that comprises electrically connecting amobile device to a USB port of a host system; uniquely identifying theUSB port and a type of the mobile device attached to the USB port;adjusting electrical performance of the USB port based on identifieddevice type and desired function; identifying a current state of themobile device; establishing a serial connection between the mobiledevice and the host system; and performing diagnostics and deviceprovisioning functions for the mobile device. An electrical performanceof the USB port may be modified, for example, by adjusting a resistancein a USB cable between the mobile device and the host system. A devicestate of the mobile device may be switched in response to identifying acurrent device state of the mobile device is not one of recovery mode ordownload mode. In another aspect, a method of the present inventionfurther comprises providing power to the mobile device through a USB thecable connected between the host system and the mobile device. Further,in another aspect, identifying a current state of the mobile devicefurther comprises determining available data connection types for themobile device. In yet another aspect of the present invention, theserial connection between the mobile device and the host systemcomprises one of a USB protocol and an RS-232 protocol. Additionally,aspects of the present invention may comprise retrieving, from themobile device, a serial number of a component installed in the mobiledevice; and determining the component is an originally installedcomponent of the mobile device. Any number and types of identifyinginformation may be obtained for components installed within the mobiledevice. One embodiment comprises obtaining a list of serial numbers ofcomponents installed in the mobile device; determining, (for examplethrough a database lookup) for each of such installed components,whether each respective component was originally installed at time ofmanufacture of the mobile device. An additional aspect involvesdetermining a resale value of the mobile device based upon at leastwhether a respective component was originally installed at time ofmanufacture of the mobile device, and in another embodiment, involvesplanning a repair or upgrade of the mobile device based upon at leastwhether a respective component was originally installed at time ofmanufacture.

Other embodiments of the present invention may include a systemcomprising a host system comprising a processor, a memory electricallycoupled to the processor, a storage device coupled to the processor, auser interface electrically coupled to the processor, and a USB portconnection coupled to the processor; the memory may be furtherconfigured with software that when executed performs the followingsteps: electrically connecting a mobile device to a USB port of a hostsystem; uniquely identifying the USB port and a type of the mobiledevice attached to the USB port; adjusting electrical performance of theUSB port based on identified device type and desired function;identifying a current state of the mobile device; establishing a serialconnection between the mobile device and the host system; and performingdiagnostics and device provisioning functions for the mobile device. Anelectrical performance of the USB port may be modified, for example, byadjusting a resistance in a USB cable between the mobile device and thehost system. A device state of the mobile device may be switched inresponse to identifying a current device state of the mobile device isnot one of recovery mode or download mode. In another aspect, a stepsexecuted by systems of the present invention further comprise providingpower to the mobile device through a USB the cable connected between thehost system and the mobile device. Further, in another aspect,identifying a current state of the mobile device further comprisesdetermining available data connection types for the mobile device. Inyet another aspect of the present invention, the serial connectionbetween the mobile device and the host system comprises one of a USBprotocol and an RS-232 protocol. Additionally, aspects of the presentinvention may comprise retrieving, from the mobile device, a serialnumber of a component installed in the mobile device; and determiningthe component is an originally installed component of the mobile device.Any number and types of identifying information may be obtained forcomponents installed within the mobile device. One embodiment comprisesobtaining a list of serial numbers of components installed in the mobiledevice; determining, (for example through a database lookup) for each ofsuch installed components, whether each respective component wasoriginally installed at time of manufacture of the mobile device. Anadditional aspect involves determining a resale value of the mobiledevice based upon at least whether a respective component was originallyinstalled at time of manufacture of the mobile device, and in anotherembodiment, involves planning a repair or upgrade of the mobile devicebased upon at least whether a respective component was originallyinstalled at time of manufacture.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete understanding of the present invention may be derived byreferring to the detailed description and claims when considered inconnection with the following illustrative figures.

FIG. 1 illustrates a schematic view of an embodiment of a system of thepresent invention.

FIG. 1A illustrates a schematic view of an embodiment of a system of thepresent invention including a resistance element electrically coupled tothe serial cable of the present invention.

FIG. 1B illustrates a schematic view of an embodiment of a system of thepresent invention wherein multiple mobile devices can be concurrentlyprocessed by the host system.

FIG. 2 depicts an exemplary flow diagram of steps used to implementaspects of the present invention.

DETAILED DESCRIPTION

An embodiment of the present invention can be understood in context ofFIGS. 1, 1A, 1B, and 2 as follows. The system 100 shown in FIG. 1 (oralternatively, 100A in FIG. 1A) executes steps to perform diagnosis onthe Device Under Test 120 (also referred to herein as “Mobile Device120”) that is electrically connected to the Host System 105 throughcable 110 (or 110A in the case of FIG. 2 ), and the cable 110 or 110Amay comprise or further comprise a USB cable. The cables 110, 110A, or110B may also optionally comprise customized cables to support variousfeatures required for serial communication in the present invention.FIG. 1B illustrates a system 100B where a plurality of Mobile Devices120B1-120B2 are respectively connected through cables 110B1-110B5 to aUSB hub 106 that is shown as part of the Host System 105. Those of skillin the relevant arts appreciate that the USB hub 106 may be internallyconnected within the Host System 105 or may be a separate componentinterfaced to the Host System 105 and subsequently connected as shown toMobile Devices 120B1-120B5. Those of skill in the art also appreciatethat while five mobile devices are illustrated as connected to the HostSystem 105, fewer or more devices may be interfaced based on theintended scale of the processing organization that is operating the HostSystem 105. The Host System 105 may comprise a computing device, withcustom or conventional components, such as a processor, a local memorysuch as RAM, non-volatile memory such as FLASH memory, long term memorysuch as a hard disk or solid date drive, a network adaptor, and anynumber of input and/or output devices such as a keyboard, mouse,monitor, touch screen, microphone, speaker, motion sensor, orientationsensor, infrared sensor, temperature sensor, humidity sensor, electricalcurrent sensor, light sensor, voltage sensor, current sensor, USB hubsas shown in FIG. 1B, and the like. In certain embodiments, the HostSystem 105 may comprise a laptop or a tablet computer configured tocommunicate with Mobile Device 120 (such as a mobile phone) thoughelectrical communications implemented by the cable 110 (such as a USBcable).

The various memories of the computing device may facilitate the storageof one or more computer instructions, such as software code and/orsoftware program, which may be executable by the processor to performthe methods of the invention. A computing device may comprise anembedded processor in such as a personal computer, a server, a mobilephone, a smart phone, a tablet computer, a kiosk, a portable computer, avehicle-embedded computer, and the like. Further, databases, systems,and/or components of the present technology may include any combinationof databases, systems, and/or components at a single location or atmultiple locations. Each database, system, and/or component of thepresent technology may comprise any suitable security features, such asfirewalls, access codes, encryption, de-encryption, compression,decompression, and the like.

The present technology may be embodied as a method, a system, a device,and/or a computer program product, for example within a mobile devicediagnostic and provisioning system. Accordingly, the present technologymay take the form of an entirely software embodiment, an entirelyhardware embodiment, or an embodiment combining aspects of both softwareand hardware. Furthermore, the present technology may take the form of acomputer program product on a computer-readable storage medium havingnon-transitory computer-readable program code embodied in the storagemedium. Any suitable computer-readable storage medium may be utilized,including any combination of hard disks, solid state drives, CD-ROM,FLASH memory, optical storage devices, magnetic storage devices, USBmemory devices, any appropriate volatile or non-volatile memory system,and the like. The present technology may include a downloadable and/orcloud-based non-downloadable computer program product and/or methods.

Software and/or software elements according to various aspects of thepresent technology may be implemented with any programming, scripting,or computer language or standard, such as, for example, AJAX, C, C++,Java, JavaScript, FORTRAN, COBOL, assembly, binary machine language,PERL, Python, Ruby, eXtensible Markup Language (XML), PHP, CSS, etc., orany other programming and/or scripting language, whether in software orfirmware, or whether now known or later developed. Further, the presenttechnology may be used in conjunction with a computing device runningany operating system such as any version of Windows, MacOS, OS/2, BeOS,Linux, UNIX, Symbian, RaspbianOS, OSX, tvOS, watchOS, TizenOS, Android,iOS, AndroidWear, or any other operating system, whether now known orlater developed.

In addition, the present technology may employ any number ofconventional techniques for data transmission, signaling, dataprocessing, network control, and the like. Computing devices accordingto various aspects of the present technology may communicate with eachother by one or more telecommunication networks. The telecommunicationnetwork may comprise a collection of terminal nodes, links, and anyintermediate nodes which are connected to enable communication(including transfer of data) at a distance between the terminal nodes.In some embodiments, a terminal node may comprise a computing device.The telecommunication network may comprise any suitable communicationsystem, such as the Internet, an intranet, an extranet, WAN, LAN, WiFi,Bluetooth, Zigbee, Z-Wave, satellite communications, cellular radionetwork, wireless network, telephone network, cable network, and thelike. Moreover, computing devices according to various aspects of thepresent technology may communicate over the telecommunication networkusing TCP/IP, HTTP, HTTPS, FTP, IPX, AppleTalk, IP-6, NetBIOS, OSI,serial communication protocols (including RS-232), and/or any number ofexisting or future protocols. The telecommunication network may besimply referred to as a network.

The cable 110 may comprise a USB cable with a connector conforming toversion 2.0, 3.x (that is, any desired implementation of USB 3), or anyother industry standard USB implementations, or may comprise any desiredcable to establish a connection to the Mobile Device 120; and further,the cable 110 may incorporate an interface compatible with the MobileDevice 120 including, but not limited to, USB mini port, a USB microport, a Lightning port, a Thunderbolt port, an Apple 30-pin port, aserial port, or any desired port to establish electrical communicationbetween the Host System 105 and the Mobile Device 120. In variousembodiments, as shown in FIG. 2 , a fixed or variable resistor 130A maybe integrated with, or electrically coupled to cable 110A to allowspecific protocols to be invoked within the hardware of the MobileDevice 120. In certain embodiments, the Host System 105 may control theresistance 130A applied to the cable 110A by altering a signal appliedto control line 133A.

A Mobile Device 120 may be electrically connected to the Host System 105at any convenient time, such as during step 295 shown in FIG. 2 . Poweris provided to the Mobile Device 120 through the cable 110 (or 110A, or110B, depending on the configuration) so if the battery state of theMobile Device 120 is completely discharged, diagnosis and provisioningmay still take place. Although in preferred embodiments, no app isinstalled on the Mobile Device 120, to accomplish certain functions itmay be desired to install an app on Mobile Device 120 should the needarise. However, a comprehensive suite of diagnostics, provisioning, anderasure functions are implemented in various embodiments of the presentinvention with no need for app installation in any step of the process.

Referring to FIG. 2 , in the Host System 105 scans 201 the Host Systemfor available USB Ports. If a USB port on the Host System 105 isdamaged, and not responsive, the process may identify such faulty portsand report to an end user of the System 100. In this manner, the enduser may be made aware that an issue exists with a specific USB port,thus reducing guesswork for the end user and avoiding an unnecessarytech support phone calls. Next, the Host System 105 scans 202 for anyUSB hubs that may be attached, as USB hubs may cause issues if they arenot properly identified before configuration and testing is undertaken.As a result of this step 202, data corruption and restore errors (inaddition to other faults) may be avoided. The embodiment of the presentinvention then scans 203 the Host System to determine whether the HostSystem is equipped with USB 2.0 Ports or USB 3.x Ports, as certaindevice types may require one USB type or the other to establish andoperate a serial connection as specified in the embodiments describedbelow. Then, the Host System 105 uniquely identifies 205 which specificUSB port a mobile device under test is attached to, which is ofparticular importance when an operation is set up to process multiplemobile devices simultaneously in an approach similar to that shown inFIG. 1B (where multiple Mobile Devices 120B1-120B5 are connected to theHost System 105).

As a next step, the Host System 105 uniquely identifies 206 everyattached mobile device that includes a particular operating system, forexample the Android operating system. Other embodiments may uniquelyidentify every iOS mobile device that is attached, and yet otherembodiments uniquely identify any device that has an operating system ofa desired type. By identifying mobile devices that are configured withparticular operating system configurations, multiple devices, evenranging into the hundreds or thousands, may be processed simultaneouslyas the subsequent processing steps may be tailored to the specificoperating system requirements of each respectively attached mobiledevice.

In one aspect, the electrical characteristics of each mobile device thatis connected to the Host System 105 are profiled 207, and if necessary,electrical performance of USB ports to which mobile devices arerespectively connected are adjusted within desired ranges based ondevice type and desired function. For example, an amount of availablecurrent flowing between a mobile device and the connected Host Systemcan be measured to ensure the mobile device is receiving the properamount of amps of current (and proper supply voltage) that is requiredby the mobile device to perform the required functions. In variousembodiments, the electrical operating characteristics of specific USBports of the present invention may be programmatically adjusted tomaintain electrical parameters (e.g. amps, volts, watts) within desiredranges. Alternatively, or in addition, a resistance 130A in the USBcable 110A may be adjusted manually or via a control signal 133Aprovided from the Host System 105A. For further example, poweroverconsumption is common with USB-C devices, and this needs to beprogrammatically controlled when processing mass quantities of devicesat once, or when a single mobile device is connected to the Host Systembut the port is not properly electrically coupled.

Embodiments of the invention then identify 208 a current devicestate/activation state of a connected Mobile Device 120, withoutinteracting with an operating system that is installed on the MobileDevice 120. Such states may include, for example, Charge Only State,DFU, Recovery Mode, Boot OS, Demo Mode, or another state. Depending onthe current state (or mode) of the Mobile Device 120, various actionsmay be undertaken to switch state of the Mobile Device 120, continueprocessing, or report to the system user. For example, if the device isin a recovery mode, or download mode, this step will identify the devicemode, and be able to trigger software executed by the Host System 105 toperform the next task without human interaction. Steps undertaken inthis step 208 or later may be tailored to the operating system installedon the particular Mobile Device 120. For example, if the Mobile Device120 is an iOS-installed device in Device Firmware Update mode (“DFU”),aspects of the present invention certain processes may be undertaken torelease the Mobile Device 120 from the DFU mode. Further, once the modeof the Mobile Device 120 has been identified, an activation state of theMobile Device 120 is then determined, and this determination is made inpart based upon the type of device.

As an advantage over prior approaches, performing the state/modeidentifying step 208 allows for proper identification of mobile devicesthat were previously assumed dead or otherwise nonfunctional, or thatcould not be identified in a mass-production scale of device recycling.As a result of this step, all available data connection types for theMobile Device 120 are identified for further processing. After step 208,diagnostic actions may be undertaken at any desired time, such as instep 211A discussed below.

In another aspect of the invention, access to the connected MobileDevice 120 is established 209 with a serial communication protocol, suchas a USB protocol or an RS-232 protocol. In certain device types, theserial connection must be established to allow devices that areconfigured with AOS, TizenOS, MacOS, WindowsOS, BBOS, WindowsPhoneOS,PebbleOS, FireOS, or SymbianOS operating systems to interoperate withthe Host System 105 to execute steps of the present invention. Those ofskill in the relevant arts appreciate that multiple serial protocolsexist, and any desired serial protocol may be utilized for any desiredpurpose in the implementation of the present invention. And in a furtheraspect, once serial connection is established, electronic access to theMobile Device 120 is established 210, allowing the mobile device to bescanned by and controlled by the Host System 105 without regard to theoperating system that is installed on the Mobile Device 120, and thusdata may be extracted from the Mobile Device 120 without the need forextraordinary measures or previous installation of an app on the MobileDevice 120. In a next aspect in FIG. 2 , a high order logic validationstep 211 is conducted, allowing for verification that all previous stepscompleted successfully, data from the Mobile Device 120 can be properlyaccessed, and the Mobile Device 120 is prepared to accept commands fromthe Host System 105 and corresponding steps in the software beingexecuted in the application running on the Host System 105.

Obtain Initial Information and Pairing Status

After high order logic validation 211 occurs, aspects of the presentinvention corresponding to diagnostics and device provisioning may takeplace 211A, or such diagnostics and device provisioning may occur aftercompletion of the process 200, or at any other desired time with respectto process 200. For example, initially a Vendor ID and Product ID valuemay be read from the Mobile Device 102. Data obtained from the MobileDevice 120 through the cable 110, (or 110A, or 110B) may have to befurther decoded to extract and identify the Product ID information.Carrier ID (that is, an identifier of the mobile service operatorprovider that provided service to the mobile device) may be obtainedfrom the Mobile Device 120 during this step or afterwards. In addition,a “pairing status” determination may be obtained from the Mobile Device120, particularly as some mobile devices such as smart watches may notbe repaired/recycled if they were previously paired with a particularmobile device and that pairing has not been cleared. As part of thepairing status assessment, aspects of the present invention determinewhat SIM card is installed, and/or whether an eSIM is utilized in theMobile Device 120. In this step, information from the SIM/eSIM card canbe obtained, and a determination can be made regarding the last activenetwork, and from that determination, aspects of the present inventiondetermine through which SIM the device was last active. Knowing thecarrier is valuable information to the recycler (and retailer) as MobileDevices 120 may be of higher value when previously associated withparticular carriers.

Determine Lock Status

Aspects of the present invention also may determine a lock status of theMobile Device 120. In various embodiments, the Mobile Device 120 isexamined to determine all possible lock states of the device, whetherthey are pin locks, passcode locks, Mobile Device Management (“MDM”)locks, Find My iPhone (“FMIP”) activation locks, or any other kind oflocks. In various embodiments, aspects of the present invention arecapable of performing diagnostic and provisioning when some lock statesare still present on the mobile device. On the other hand, some lockstates may indicate that further processing for the particular mobiledevice should be immediately discontinued; for example, if an iOS-basedmobile device is locked through an FMIP Activation Lock, the device maybe quickly identified to discontinue testing (potentially savingextensive diagnosis and look up through third party databases todetermine FMIP status). Also as part of this step, a determination maybe made as to whether Mobile Device 120 was jailbroken (in the case ofiOS) or rooted (in the case of Android). In many circumstances,recyclers do not wish to recondition previously jailbroken or rootedmobile phones as the potential exists for residual malware remaining onsuch devices. Early identification of jailbroken and/or rooted statetherefore saves the recycler time in performing diagnostics andattempted erasure.

Obtain General Information from Mobile Device.

In yet another embodiment, provided that the device is remainsaccessible based on its lock status, general information is obtainedfrom the mobile device and logged within the Host System 105. Suchgeneral information may include information that is valuable to a devicerecycler or a retail operation, such as the device's registered modelnumber, color, marketing name, IMEI, operating system version number,firmware version number, serial number, memory size, rooted/jailbrokenstatus (as mentioned above), and carrier ID/carrier code, among otherthings. In one aspect, a first collection of information may be obtainedfrom an Android-based Mobile Device 120 where ADB has not beenactivated, and a second larger set of information may be obtained ifembodiments of the present invention activate ADB on the Mobile Device120. In another aspect, full identification of over 20,000 parameters iniOS-based devices may be obtained by aspects of the present inventionwithout first installing an app on an iOS-based mobile device. Generalinformation, once obtained from the Mobile Device 120 by the Host System105 is stored for presentation to the end user, or for use in furtherprocessing particular diagnostics or provisioning steps.

Extract and Identify Auto-Diagnostics

Many types of mobile devices conduct routine internal diagnostics andstore the results of the diagnostics in the mobile device in a varietyof ways including diagnostic logs. These “auto-diagnostic” test resultlogs are not normally accessible to the end user, and may be difficultto understand in their encoded form, yet contain information that onceread and decoded can quickly indicate to a device recycler or end user afunctional condition of the mobile device; further, such information mayindicate components needing repair or adjustment thus guiding a recyclerin planning for refurbishment. In various aspects of the presentinvention, information obtained from logs stored within the MobileDevice 120 is obtained and decoded by the Host System 105, and thoselogs are utilized to determine whether various features of the MobileDevice 120 are operating within normal parameters based on expectedoperational criteria stored within the operating system of the MobileDevice 120.

Regarding embodiments where the iOS operating system is installed onMobile Device 120, a list of device “entitlements” are obtained by theHost System 105 from the firmware of the Mobile Device 120, and the“entitlements” provide a list of information, features, and commandsthat the particular Mobile Device 120 may be instructed to perform orreport. In this way, a list of potential functions is determined bychecking the firmware of the Mobile Device 120, providing for thepreparation of a set of diagnostics and provisioning functions used bythe mobile device. By analyzing the list of possible commands andreports available for a particular Mobile Device 120, efficiencies arerealized in the diagnostics process by restricting actions andinformation gathering to available functions and reporting based on theparticular configuration of the Mobile Device 120. In variousembodiments, data may be extracted, decoded, and decompiled based uponcertain mapping information obtained from firmware of the Mobile Device120. Such extracted and decoded information may identify allowablediagnostic ranges for device performance that allow for configuration ofthe diagnostic software; without such information, in many instances,the person conducting the diagnostic tests may need to guess atallowable performance value ranges and these may lead to incomplete ornon-comprehensive device testing. Further, efficiencies are improved fordevice recyclers or retailers by early identification of “hard stop”conditions such as an activation lock state that renders devices 120inaccessible for further diagnostics, provisioning, or recycling.

Based on the device type/operating system type, certain custom actionsmay be undertaken by aspects of the present invention. For example, inthe case of Android-based devices 120, certain diagnostic informationand commands may be optionally obtained and/or executed by activatingthe Android Debug Bridge (“ADB”) through commands sent from the HostSystem 105 through a serial connection (such as through the cable 110)between the Host System 105 and the Mobile Device 120, and operatingsystem-based information may be obtained and commands executed on theMobile Device 120 without installing an app on the Mobile Device 120. Invarious embodiments, discussed below, ADB may be manually activated by auser of Host System 105, or for particular types of Mobile Devices 120,ADB may be autonomously activated by the software of the Host System105.

Device Provisioning

Commands may be executed on the Mobile Device 120 to prepare it forresale or re-use, or to otherwise process it for its final disposition.One of such functions may include device erasure that can beaccomplished through invoking built-in erasure algorithms that areutilized by the operating system to fully erase the mobile device. Inprior approaches, recyclers or retailers commonly installed an app onthe Mobile Device 120 to perform erasure, but this process can beextremely time consuming compared to native device erasure invoked bythe Host System 105 through its interface to the Mobile Device 120.Erasure of the Mobile Device 120 may be certified by any desiredtechnique, such as by taking a fingerprint of the mobile device'smemory, invoking the device native erasure software, allowing erasure tooccur, then re-pairing the Mobile Device 120 with the with the HostSystem 105 to confirm that the fingerprinted memory is no longer presentwithin the Mobile Device 120.

Diagnostic Data Presentation

Information that has been obtained from the Mobile Device 120 isprocessed and presented, for example thorough a user interface, to theoperator of the Host System 105. In various embodiments, the operator ofthe Host System 105 may select how much information is to be presented,in what arrangement, and with specific content and order.

The above-described process steps of the present invention may bedirectly executed, partially executed, or executed after the illustratedprocess 200 terminates 212. Before termination 212, a Device DataCleanup process 212 may be undertaken in various aspects of theinvention, to quickly and administratively clean the Host System 105 toremove any undesired data, logs, or information. This process 212 can beexecuted after every completion of mobile device processing, or at theend of a batch device processing session.

EMBODIMENTS OF THE PRESENT INVENTION: FEATURE SET ONE

As mentioned above, various diagnostic functions and provisioningprocesses may be executed on the Mobile Device 120. In a first aspect, aset of features provided by embodiments of the present inventionincludes, but is not limited to the following six features:

1. Serial Connection for Advanced Diagnostics and Provisioning: In oneaspect of the present invention, a serial connection between the HostSystem 105 and the Mobile Device 120 is established, and the serialconnection provides a mechanism to support low-level access to hardwarecomponents and firmware. Establishing such serial connection allowsaccess to a rich set of device diagnostic information and built-incommands in a mobile device without first requiring installation of anapp on the mobile device.

2. Implementation of a DFU Eraser: for iOS-based devices, an improvederasure process can be invoked through the Host System 105 commandingthe Mobile Device 120 to enter DFU mode, and activating an erasurealgorithm in the Mobile Device 120. Such erasure provides a faster andmore complete mode of erasure, and afterwards, the Mobile Device 120 maybe paired and a registry event searched to determine whether there wasan “Obliteration” event logged; the results of the erasure validationmay be presented on certification of erasure that is uniquely associatedwith the particular Mobile Device 120 that was erased.

3. MDM Detection: aspects of the present invention provide for MobileDevice Management (“MDM”) detection to allow early identification ofdevices that may have an MDM lock enabled; if such devices are in modesthat are inaccessible or otherwise unable to be reconfigured, earlyidentification of MDM mode provides for a quick termination of thediagnostic testing, thus saving the recycler time and improvingefficiency by identifying devices for redisposition.

4. eSIM Erasure: mobile devices (particularly those using the iOSoperating system) are increasingly incorporating embedded SubscriberInformation Modules for network authentication. Aspects of the presentinvention allow the Host System 105 to command the Mobile Device 120 toinitiate erasure of its eSIMs (or, alternatively, SIMs), thusconfiguring the device for use by a new purchaser, and removing prioruser information (and potential Personally Identifiable Information or“PII”) from the Mobile Device 120 before the Mobile Device 120 isreturned to the stream of commerce.

5. Skip iOS UI Setup: in some mobile devices, particularly thoseutilizing the iOS operating system, performing certain functions such asinstalling and launching an app on the mobile device requires the app tobe “trusted” through user input. To provide such input indicating trust,the Mobile Device 120 typically must be user accessible; further, onnewly-configured/flashed devices, the setup process is often lengthy andrequires user entry of information such as WiFi credentials, region ofoperation, and user trust inputs. In various embodiments of the presentinvention, the Host System 105, through its connection to the MobileDevice 120 performs functions to skip the normal iOS UI setup process onthe Mobile Device 120, thus saving significant amount of time during thediagnostic and provisioning process. Also thereby, further operationssuch as providing indications of app trust may be undertaken withminimal delay.

6. Serial Component Identification and OEM Component Configuration:embodiments of the present invention, through connection of the HostSystem 105 to the Mobile Device 120, provide functions that obtain alist of serial numbers of components installed in the Mobile Device 120,allowing a determination through a database lookup of whether suchcomponents are original OEM components or were after-market componentsinstalled after initial manufacture. This information allows mobilerecyclers to more accurately determine value of the devices for resale,particularly for iOS-configured devices, and to plan any necessaryupgrades or repair of components currently installed in the MobileDevice 120. Along with the serial component identification, Carrier IDmay be obtained and verified for a particular Mobile Device 120.

EMBODIMENTS OF THE PRESENT INVENTION: FEATURE SET TWO

As mentioned above, various diagnostic functions and provisioningprocesses may be executed on the Mobile Device 120. In a second aspect,a set of features provided by embodiments of the present inventionincludes, but is not limited to the following four features:

1. Android Rapid Erasure with Validation: for Android-configured mobiledevices, in embodiments of the present invention, a “native” Androidcommand is remotely executed by first activating, through user input, anADB mode of operation of the mobile device. By executing erasurealgorithms already present on the Mobile Device 120, the erasure processcompletes far more quickly than the previous processes that firstrequired an app to be installed on the Mobile Device 120. Connectivitybetween the Host System 105 and the Mobile Device 120 is maintainedduring erasure, and after erasure is complete, storage on the MobileDevice 120 is read by the Host System 105 to confirm whether erasure wassuccessful. If embodiments of the present invention determine erasurewas successful, then a Certificate of Erasure uniquely associated withthe Mobile Device 120 may be generated to confirm erasure to subsequentusers of the Mobile Device 120.

2. Auto ADB Rapid Erasure with Validation. Similar to the Android RapidErasure with Validation above, aspects of the present invention cause anative erasure tool on the Mobile Device 120 to erase data from theMobile Device 120 thorough first activating the Android Debug Bridgewithout user input. For devices supporting this option, this embodimentprovides a more streamlined approach as users do not need to manuallyactivate ADB before executing a native erasure algorithm on the MobileDevice 120. As before, after erasure is complete, storage on the MobileDevice 120 is read by the Host System 105 to confirm whether erasure wassuccessful. If embodiments of the present invention determine erasurewas successful, then a Certificate of Erasure uniquely associated withthe Mobile Device 120 may be generated to confirm erasure to subsequentusers of the Mobile Device 120.

3. Extract Device Configuration Fingerprint: in various situations, itmay be useful to a particular recycler, mobile carrier, or other entityto understand the exact configuration of hardware and software installedin a particular mobile device. Embodiments of the present inventionutilize the connection between the Host System 105 and the Mobile Device120 to generate a comprehensive manifest, or “fingerprint,” of themobile device hardware and software. This configurationmanifest/fingerprint can then be compared, for example, to a desired“golden” manifest to determine whether the mobile device conforms tonecessary minimum standards to operate within a particular network, orto determine whether the device meets other minimum functionalperformance measures. In various embodiments, core device details andinformation may be obtained without first installing an app on theMobile Device 120.

4. Android Diagnostics: In various embodiments, automated diagnosticssimilar to those described above will be initially performed on Androiddevices. At the same time, rapid diagnostics may be executed by the HostSystem 105 on the Mobile Device 120 with or without applications beinginstalled first on the Mobile Device 120.

EMBODIMENTS OF THE PRESENT INVENTION: FEATURE SET THREE

As mentioned above, various diagnostic functions and provisioningprocesses may be executed on the Mobile Device 120. In a third aspect, aset of features provided by embodiments of the present inventionincludes, but is not limited to the following two features:

1. Automatically Enabling Android Debug Bridge (ADB) Mode for CertainDevices: in various embodiments of the present invention, some mobiledevice types may be commanded by the Host System 105 to automaticallyenable ADB mode to support the performance of advanced diagnostics andprovisioning without user intervention. By providing for rapid access toADB-enabled functionality, aspects of the present inventionsignificantly streamline the diagnostic process by allowing diagnosticand provisioning functions to be undertaken with minimal to no userintervention and without first installing an app on the mobile device.

2. Apple Watch Error Indicator Mitigation: in some instances, such aswhen an error occurs during an update of an Apple Watch, the operatingsystem of the watch may display a red exclamation mark, and in thismode, the watch is incapable of further normal operation. For mobiledevice recyclers, this error condition previously indicated a hard stopin the recycling process and the watch would typically be sent forparting out or scrapping. In various aspects of the present invention,an Apple watch displaying a red exclamation mark is interfaced to aconnection jig that is connected to a test system such as Host System105, and embodiments of the present invention may perform functions onthe mobile watch such as: removing the red exclamation error state,reading memory of the watch to determine whether data has beenpreviously stored on the watch, and obtaining diagnostic information oncomponents of the watch such as its crown or battery.

The particular implementations shown and described herein areillustrative of the invention and its best mode and are not intended tootherwise limit the scope of the present invention in any way. Indeed,for the sake of brevity, conventional data storage, data transmission,and other functional aspects of the systems may not be described indetail. Methods illustrated in the various figures may include more,fewer, or other steps. Additionally, steps may be performed in anysuitable order without departing from the scope of the invention.Furthermore, the connecting lines shown in the various figures areintended to represent exemplary functional relationships and/or physicalcouplings between the various elements. Many alternative or additionalfunctional relationships or physical connections may be present in apractical system.

Changes and modifications may be made to the disclosed embodimentswithout departing from the scope of the present invention. These andother changes or modifications are intended to be included within thescope of the present invention, as expressed in the following claims,which illustrate non-limiting embodiments of the present invention.

What is claimed is:
 1. A method comprising: electrically connecting amobile device to a USB port of a host system; uniquely identifying theUSB port and a type of the mobile device attached to the USB port;adjusting electrical performance of the USB port based on identifieddevice type and desired function; identifying a current state of themobile device; establishing a serial connection between the mobiledevice and the host system; performing diagnostics and deviceprovisioning functions for the mobile device; obtaining a list of serialnumbers of components installed in the mobile device; determining, foreach of such installed components, whether each respective component wasoriginally installed at time of manufacture of the mobile device; and atleast one of: determining a resale value of the mobile device based uponat least whether a respective component was originally installed at timeof manufacture of the mobile device; and planning a repair or upgrade ofthe mobile device based upon at least whether a respective component wasoriginally installed at time of manufacture.
 2. The method of claim 1,wherein adjusting electrical performance of the USB port comprisesadjusting a resistance in a USB cable between the mobile device and thehost system.
 3. The method of claim 2, wherein the method comprisesswitching a device state of the mobile device in response to identifyinga current device state of the mobile device is not one of recovery modeor download mode.
 4. The method of claim 1, further comprising providingpower to the mobile device through a USB the cable connected between thehost system and the mobile device.
 5. The method of claim 1, whereinidentifying a current state of the mobile device further comprisesdetermining available data connection types for the mobile device. 6.The method of claim 1, wherein the serial connection between the mobiledevice and the host system comprises one of a USB protocol and an RS-232protocol.
 7. The method of claim 1, further comprising: retrieving, fromthe mobile device, a serial number of a component installed in themobile device; and determining the component is an originally installedcomponent of the mobile device.
 8. A system comprising: a host systemcomprising a processor, a memory electrically coupled to the processor,a storage device coupled to the processor, a user interface electricallycoupled to the processor, and a USB port connection coupled to theprocessor, wherein the memory is further configured with software thatwhen executed performs the steps of: electrically connecting a mobiledevice to a USB port of the host system; uniquely identifying the USBport and a type of the mobile device attached to the USB port; adjustingelectrical performance of the USB port based on identified device typeand desired function; identifying a current state of the mobile device;establishing a serial connection between the mobile device and the hostsystem; performing diagnostics and device provisioning functions for themobile device; obtaining a list of serial numbers of componentsinstalled in the mobile device; determining, for each of such installedcomponents, whether each respective component was originally installedat time of manufacture of the mobile device; and at least one of:determining a resale value of the mobile device based upon at leastwhether a respective component was originally installed at time ofmanufacture of the mobile device; and planning a repair or upgrade ofthe mobile device based upon at least whether a respective component wasoriginally installed at time of manufacture.
 9. The system of claim 8,wherein adjusting electrical performance of the USB port comprisesadjusting a resistance in a USB cable between the mobile device and thehost system.
 10. The system of claim 9, wherein the system comprisesswitching a device state of the mobile device in response to identifyinga current device state of the mobile device is not one of recovery modeor download mode.
 11. The system of claim 8, further comprisingproviding power to the mobile device through a USB the cable connectedbetween the host system and the mobile device.
 12. The system of claim8, wherein identifying a current state of the mobile device furthercomprises determining available data connection types for the mobiledevice.
 13. The system of claim 8, wherein the serial connection betweenthe mobile device and the host system comprises one of a USB protocoland an RS-232 protocol.
 14. The system of claim 8, further comprising:retrieving, from the mobile device, a serial number of a componentinstalled in the mobile device; and determining the component is anoriginally installed component of the mobile device.